Facile Cu–MOF-derived Co3O4 mesoporous-structure as a cooperative catalyst for the reduction nitroarenes and dyes

The present study describes the environmentally friendly and cost-effective synthesis of magnetic, mesoporous structure-Co3O4 nanoparticles (m-Co3O4) utilizing almond peel as a biotemplate. This straightforward method yields a material with high surface area, as confirmed by various characterization techniques. Subsequently, the utilization of m-Co3O4, graphene oxide (GO), Cu(II)acetate (Cu), and asparagine enabled the successful synthesis of a novel magnetic MOF, namely GO–Cu–ASP–m-Co3O4 MOF. This catalyst revealed remarkable stability that could be easily recovered using a magnet for consecutive use without any significant decline in activity for eight cycles in nitro compound reduction and organic dye degradation reactions. Consequently, GO–Cu–ASP-m-Co3O4 MOF holds immense potential as a catalyst for reduction reactions, particularly in the production of valuable amines with high industrial value, as well as for the elimination of toxic-water pollutants such as organic dyes.

On the other hand, nanomagnetic catalysts are highly attractive because of their ease of isolation and reusability.Various nanoparticles with magnetic properties were broadly synthesized and utilized in wide range of applications [32][33][34][35] .Co 3 O 4 is an encouraging material due to its environmental benignity, excellent activity, low cost, and morphology-dependent properties 36 .In the past, the synthesis of Co 3 O 4 has involved hazardous solvents or complicated processes.However, recent advancements have enabled the synthesis of Co 3 O 4 using biotemplates instead of harsh chemicals 37,38 .Additionally, pollen-assisted CeO 2 /Co 3 O 4 hollow microspheres have been developed for photocatalytic applications 39 .
Graphene oxide (GO) is a promising candidate as a support for improving the catalytic performance of transition-metal catalysts due to its excellent surface's properties 40 .GO has been positively operated as a support for dispersing as well as stabilizing metal nanoparticles 41 .Due to the attractive dispersion of GO in aqueous solution, is known as a support for the fabrication of water-soluble nanocarbon.
Motivated by these considerations and our ongoing research in heterogeneous catalysts field [65][66][67][68][69][70][71][72][73][74] , we current our findings on the decoration and synthesis of a new magnetic MOF-based catalyst containing m-Co 3 O 4 .This catalyst is fabricated through a stepwise functionalization process, where graphene oxide (GO) is functionalized with Cu(OAc) 2 and asparagine (ASP), and then coordinated with m-Co 3 O 4 , resulting in the creation of the porous magnetic MOF structure.Notably, we successfully utilize almond peel as a template to synthesize porous Co 3 O 4 nanoparticles with magnetic properties.Almond shell as a natural, hydrophilic and cost-effective template composed of hemicelluloses, lignin and cellulose 75 , plays a fundamental role in determining the morphology and surface area of prepared m-Co 3 O 4 nanoparticles.The catalyst structure is confirmed by various standard techniques, and its performance towards the nitroarenes, MB and CR reduction under ambient reaction conditions is assessed.This result demonstrate that GO-Cu-ASP-m-Co 3 O 4 MOF as a catalyst displays promising catalytic behavior, surpassing that of other catalysts reported in this field.Moreover, it has the potential to enhance the durability of various catalytic progressions.

Catalyst characterization
After successful completion of catalyst synthesis, various techniques were employed to identify the catalyst.Initially, the stepwise synthesis of GO-Cu-ASP-m-Co 3 O 4 MOF, including GO (A), GO-Cu (B), GO-Cu-ASP (C), Almond peel (D), Co 3 O 4 (E) and GO-Cu-ASP-m-Co 3 O 4 MOF (F) were investigated and identified using FTIR analysis (Figure S1).The absorption bands at 1050, 1222, 1614, 1728 and 3444 cm −1 in Figure S1A correspond to C-O, C-OH, C=C, C=O, and O-H groups in the structure of GO.In Figure S1B, a slight redshift in the absorption bands in 1200-1600 cm −1 indicates the loading of Cu particles onto the GO sheets.The significant absorption band at 1658 cm −1 in Figure S1C confirms the presence of an -CONH 2 group and its interaction with GO-Cu.The absorption bands observed at 1622, 1735, 2927 and 3427 cm −1 in Figure S1D resemble to stretching vibrations of the C=C, C=O, O-H, and N-H, respectively, indicating the presence of almond peel.Additionally, two distinctive absorption bands at 567 and 634 cm −1 in Figure S1E provided evidence for the successful synthesis of magnetic m-Co 3 O 4 (Figure S1E).The final catalyst's FTIR spectrum (Figure S1F) confirms the presence of all the absorption bands from the previous stages, albeit with slightly reduced peak intensities, indicating the stepwise incorporation of each stage into the magnetic catalyst GO-Cu-ASP-m-Co 3 O 4 MOF.
The Raman spectra of m-Co 3 O 4 and GO-Cu-ASP-m-Co 3 O 4 MOF are depicted in Figure S2, revealing two distinct absorption bands at 1335 cm −1 (D band associated with sp 3 configuration) and 1570 cm −1 (G band attributed to graphitic carbon) for catalyst.As observed in Figure S2, D and G bands are fully preserved in the final catalyst, providing evidence for the successful synthesis of GO-Cu-ASP-m-Co 3 O 4 MOF.Additionally, the I D /I G ratio of 0.85 signifies a carbonaceous catalyst structure with some degree of disorder.It is noteworthy that m-Co 3 O 4 exhibits several active Raman modes at ∼185, 465, 507, 604, 680, and 750 cm −1 .Excluding the last mode, all observed modes are in agreement with the values of pure Co 3 O 4 spinel structure 79 yet with an average shift to right after functionalization with some reagents.While the Raman mode at 680 cm −1 is attributed to characteristics of the octahedral sites A 1 g, the Eg, and F 2 g modes are related to the combined vibrations of tetrahedral site and octahedral oxygen motions.Moreover, the average shift may be attributed to size effects or surface stress/strain.
The thermogravimetric analysis of GO-Cu (A), m-Co 3 O 4 (B), and GO-Cu-ASP-m-Co 3 O 4 MOF (C) was conducted at 25-700 °C, N 2 atmosphere.Figure S3A depicts the TGA curve of GO-Cu, which exhibits two distinct decomposition stages within 25-700 °C.The first loss at 130 °C can be attributed to removal of hydroxyl groups and water.Subsequently, a second significant decomposition stage occurs between 190 and 400 °C, corresponding to the degradation of carboxylic groups and the release of CO 2 gas.As shown in Figure S3B, corresponding to m-Co 3 O 4 , a satisfactory level of thermal stability was observed with minimal degradation.In the TG curve of GO-Cu-ASP-m-Co 3 O 4 MOF, in addition to water and moisture loss, a major degradation event was observed within 230 to 450 °C, indicating better thermal stability compared to GO-Cu.GO-Cu-ASP-m-Co 3 O 4 MOF undergoes decomposition with increasing temperature, releasing N 2 and CO 2 gases from its molecular structure.
To assess the structural characteristics of m-Co 3 O 4 and GO-Cu-ASP-m-Co 3 O 4 MOF, BET analysis was employed.Both isotherms displayed type II behavior with H3 hysteresis loops, demonstrating the porous structure that is retained after functionalization (Fig. 2A,C).The specific surface area, total pore volume, and average pore diameter of m-Co 3 O 4 were determined as 14.11 m 2 g −1 , 0.0693 cm 3 g −1 19.65 nm, respectively.For GO-Cu-ASP-m-Co 3 O 4 MOF, two values increased to 24.13 m 2 g −1 , 0.108 cm 3 g −1 and pore diameter decreased to 17.90 nm.The heightened specific surface area and overall pore volume following the functionalization of GO-Cu indicate the successful incorporation of metal particles and the establishment of interconnections between the two porous structures.In agreement with BJH isotherms (Fig. 2B,D), m-Co 3 O 4 exhibits two types of pores: micropores and mesopores with sizes of 3.5 and 25 nm, respectively, which after functionalization and Nevertheless, the final catalyst still possessed favorable magnetic properties, enabling its effortless separation from the mixture by applying a magnet.
SEM/EDX analysis was accompanied to probe the morphology of Almond peel, m-Co 3 O 4 , GO-Cu-ASP-m-Co 3 O 4 MOF, GO-Cu and GO-Cu-ASP.In Figure S5A, almond peel possesses a honeycomb-like structure with distinct layered features, and it exhibits a highly mesoporous nature.Based on the EDX result (Figure S5B), the almond peel contains various elements, including carbon (56.55%), oxygen (34.83%), calcium (3.27%), silica (0.57%) and nitrogen (4.82%).In Figure S5C, SEM image displays a cavity-like morphology (predominantly) and rod-like structures of Co 3 O 4 (C).As shown in Figure S5D, EDX analysis of Co 3 O 4 confirms its elemental composition, consisting of carbon (5.45%), nitrogen (0.52%), oxygen (2.99%), calcium (0.47%), and cobalt (90.5%).These observations provide evidence of the successful synthesis of Co 3 O 4 .Furthermore, Figure S5E and F depict the images of GO-Cu and GO-Cu-ASP, respectively.GO-Cu represents GO sheets, while GO-Cu-ASP corresponds to a specific form of GO-Cu modified with asparagine.Figure S5G and H reveal the final structure of the catalyst, which consists of a combination of m-Co 3 O 4 and GO-Cu-ASP.Overall, GO-Cu-ASP-m-Co 3 O 4 MOF exhibits well-defined cavity, layered, and rod-like structures in some parts.The EDX analysis of GO-Cu-ASP-m-Co 3 O 4 MOF indicates the presence of carbon (12.01%), nitrogen (2.01%), oxygen (4.68%), silica (0.1%), calcium (0.24%), cobalt (80.57%), and copper (0.39%), confirming the correct synthesis of the catalyst.The results obtained from the EDX analysis were consistent with those obtained from ICP-OES.The Cu and Co loadings were determined to be 0.0028 mmol g −1 and 0.11 mmol g −1 , respectively.Additionally, the amounts of Cu and Co leaching after las recycle were calculated as 0.0024 mmol g −1 and 0.086 mmol g −1 , respectively.
As illustrated in Fig. 3, the images acquired from HRTEM analysis vividly depict the thin layers of GO containing dark-colored spherical particles that remain intact after surface modification and catalyst structure refinement.Moreover, GO layer containing Cu species, exhibiting substantial interaction with the elongated m-Co 3 O 4 nano rods and finely shaped copper nanoparticles.Figure 3A-D exhibit the significant interaction of GO-Cu-ASP sheets with long m-Co 3 O 4 nano rods.The MOF structure is well-formed by these constituents.Cu presence, characterized by small particle sizes, is distinctly observable according to the SAED image.The SAED pattern confirms the presence of it and reveals size ranging from 20 to 55 nm (Fig. 3F).

Investigation of the catalytic activity
To assess the performance of GO-Cu-ASP-m-Co 3 O 4 MOF catalyst, the reduction of 4-nitrophenol (4-NP) was nominated as a model reaction.The reaction conditions were optimized by varying the catalyst dosage, NaBH 4 concentration, water content and prospering of active site (refer to Table S1 and Figure S6 for details).The presence of GO-Cu-ASP-m-Co 3 O 4 MOF proved to be essential for the reduction reaction, as no reduction www.nature.com/scientificreports/activity was detected without any catalysts (Table S1, entry 11).Based on the optimization of catalyst amounts, 30 mg of GO-Cu-ASP-m-Co 3 O 4 MOF was selected for further experiments due to its high conversion rate (Table S1, entries 4-10).The use of very high or low amounts of GO-Cu-ASP-m-Co 3 O 4 MOF was found to be less suitable, as it led to longer reaction times despite complete conversion.The effect of NaBH 4 content (0, 5, 7.5, and 10 mmol) on the reduction process was investigated.Table S1 shows that the highest efficiency and absence of side products were achieved when 7.  band appeared at 300 nm, indicating the formation of the 4-AP product.The lack of change in the intensity of this peak over time confirms that the reduction is not possible without a catalyst.Following optimization of the reaction conditions, the GO-Cu-ASP-m-Co 3 O 4 MOF was employed for the reduction of nitroaromatic compounds.As presented in Table 1 and Figure S7, the catalyst exhibited high reactivity and efficiency in reducing a wide range of nitroaromatic compounds, including those with electron-donating and -withdrawing compounds, as well as nitrobenzene.Notably, the catalyst not only reduced the nitro group but also induced bond cleavage in certain cases.For example, in the case of 4-nitrophenylpalmitate, the catalyst not only reduced the nitro group but also broke the bond between the -O and -C=O groups, resulting in the formation of 4-AP (Table 1, entry 5).Likewise, 4-nitrobenzaldehyde, 4-nitrobenzoic acid and 4-nitroacetophenone were reduced to 4-aminobenzyl alcohol, 4-aminobenzaldehyde and 4-aminostyrene, respectively (Table 1, entries 12-14).The solid products were confirmed by melting point determination, and the structures of several products were identified through GC-MS analysis (refer to Figure S8-S12 in the Supplementary Information).It should be noted that selectivity of all compounds were 100% because this catalyst could promote the reduction very well and the products of this reaction were single products and did not show any side products during the reaction.
Based on the mechanism proposed in recent studies on 4-NP reduction 80,81 , a catalyst can provide an active surface for catalytic reduction.Upon addition of NaBH 4 , 4-NP is protonated and forms 4-nitrophenolate as an intermediate.The reduction process commences with the addition of GO-Cu-ASP-m-Co 3 O 4 MOF and the transfer of hydride from NaBH 4 to 4-NP.Once all the oxygen in the system is consumed, the reduction of 4-NP commences.The distribution and accumulation of hydrogen gas bubbles on the catalyst and within the reaction environment create favorable conditions for catalytic reduction.Subsequently, a water molecule is released from the catalyst surface, allowing for the release of 4-AP and initiating the next catalytic cycle.The proposed mechanism for this reaction is represented in Figure S13.
The proposed mechanism, as well as experimental results, unequivocally demonstrate the indispensable role of a reducing agent, in conjunction with a catalyst containing an active metal, in facilitating the reaction.To investigate the influential factors affecting the progress of the 4-NP reduction process, a model reaction was conducted using controlled catalysts at various stages of the catalyst synthesis (Table S1).The control samples exhibited no observable color changes or product formation, underscoring the necessity of an active site, particularly a metal, for effective catalysis (Table S1, entries 13-17 and Figure S6).For instance, GO is unable to promote the reaction as it lacks any active sites for reaction advancement, while, the presence of copper metal is highly suitable for the reduction process and enhances the reaction's yield up to 35%.Additionally, the inclusion of cobalt (Co) nanoparticles, in addition to copper (Cu), had a pronounced effect on the reaction progress, resulting in an efficiency exceeding 50%, which can be attributed to the synergistic effect of two metals.Notably, the most favorable outcomes were obtained with the final catalyst, owing to synergistic effect of Cu, Co, and GO within the MOF structure.The UV-Vis spectra of these processes in the presence of the catalyst are presented in Figure S6.Finally, the recyclability of GO-Cu-ASP-m-Co 3 O 4 MOF in reducing 4-NP was investigated.To this purpose, after each run GO-Cu-ASP-m-Co 3 O 4 MOF was magnetically separated, washed, dried, and reused in subsequent reactions and prepared for re-uses in similar reactions.As depicted in Figure S14D, the catalyst exhibited recyclability up to eight runs without a significant decrease in conversion.Additionally, SEM/EDX and FTIR also confirmed the structural stability of the recycled catalyst without any noticeable structural changes (Figures S14A,  B and C).To further explore the observed decrease in efficiency, an investigation into the leaching of Cu and Co elements was conducted following the third (0.0003 mmol g −1 and 0.012 mmol g −1 ) and final (0.0024 mmol g −1 and 0.086 mmol g −1 ) recoveries, respectively.The findings indicate that while a minor reduction in efficiency may be anticipated due to the presence of residual materials within the catalyst structure, leading to the obstruction of specific active sites.Consequently, this reduction in reaction efficiency may be attributed to the entrapment of copper species, consequently blocking the active sites.

Materials and instruments
The experimental section provides details on the materials and instruments used, including the chemicals and reagents, as well as the characterization techniques employed to analyze the structure of the GO-Cu-ASP-m-Co 3 O 4 MOF.All chemicals and reagents, including, Almond peel, graphite powder, H 2 SO 4 , H 3 PO 4 , NaNO 3 , H 2 O 2 (30%), NH 3 .H 2 O, NaBH 4 , TEOS, MB, CR, asparagine, triethylamine, nitro compounds, cobalt(II)nitrate, copper(II)acetate, toluene, methanol, ethanol, and deionized water, were analytical grade reagents purchased from Sigma-Aldrich and used without further purification.The progress of organic reactions was monitored using thin-layer chromatography (TLC) on aluminum plates coated with silica gel 60 F254 and UV-Vis spectroscopy was performed using an Analytik Jena Specord S 600 BU.GC-MS analysis was conducted using an N/5973N6890A Agilent Technologies instrument.The melting point of solid compounds was determined using an electrothermal 9100 apparatus with open capillaries.After the synthesis of the GO-Cu-ASP-m-Co 3 O 4 MOF, its structure was characterized using various techniques, including Raman spectroscopy, XRD, TGA, FTIR, VSM, SEM/EDX, BET, HRTEM, and ICP-OES.Raman analyses were performed using a Teksan-N1-541 Spectrum with a wavelength of k = 532 nm.X-ray diffraction patterns were obtained using a Siemens D5000.CuKα instrument in the range of 2θ = 5-90° from a sealed tube.The catalyst was subjected to thermogravimetric analysis (TGA) using a heating rate of 10 °C/min up to a temperature of 700 °C under a nitrogen atmosphere.FTIR spectra were obtained using a PERKIN-ELMER-Spectrum 65 instrument.BET analysis was performed using a BELSORP Mini II instrument, with the samples being degassed at 425 K for 1.5 h.SEM/EDX and HRTEM images were recorded using TESKAN VEGA III LMU and HRTEM FEI Tecnai G 2 F20 instruments, respectively.VSM analysis was conducted at room temperature using a Vibrating Sample Magnetometer (Model 7300 VSM system, Lake Shore Cryotronic, Inc., Westerville, OH, USA).ICP-OES analysis was performed using a Varian-Vista-pro instrument.

Preparation of GO (1)
The synthesis of the GO-Cu-ASP-m-Co 3 O 4 catalyst involved a series of well-defined procedures.Initially, GO was synthesized from graphite using a Hummer's method with slight adjustments 82 .A mixture of graphite (2.5 g) and sodium nitrate (1.25 g) was combined, followed by the addition of concentrated H 2 SO 4 (54 mL) and H 3 PO 4 (6 mL) under continuous stirring.Care was taken to maintain the temperature below 15 °C during the gradual addition of KMnO 4 (7.5 g) to avoid overheating and potential explosion and then it was stirred at 40 °C for 2 h and subsequently diluted with distilled water (69 mL) under continued stirring before being subjected to reflux at 90 °C.After an hour, the reflux was terminated, and cold distilled water (100 mL) was cautiously introduced into the reaction mixture, followed by the gradual addition of H 2 O 2 (7.5 mL).The resulting mixture underwent thorough washing with water, subsequent centrifugation, and finally drying at 80 °C for 16 h, yielding GO sheets (1).

Synthesis of GO-Cu (2)
To achieve the synthesis of GO-Cu, a meticulously executed procedure was implemented.Initially, a suspension of GO (3 g) in toluene (60 mL) is prepared and subjected to continuous stirring until a homogeneous state was attained.Subsequently, a solution containing copper(II)acetate in methanol (0.6 g, 10 mL) introduced into the aforementioned suspension, and the mixture underwent reflux for a duration of 18 h.Following this reflux process, a precipitate (2) materialized, which was subsequently isolated through filtration, carefully washed by MeOH/toluene, subsequently dried under air.

Synthesis of GO-Cu-ASP (3)
In order to accomplish this objective, a solution of GO-Cu (3 g) was dispersed in a combination of hot distilled water (15 mL) and ethanol (35 mL) using ultrasonic irradiation (100 W) for a specified duration.Subsequently, asparagine (9 g) and trimethylamine (2 mL) were subjected into the mixture and dispersed for an additional duration.The new mixture was then subjected to reflux at 75 °C with vigorous mechanical stirring under an atmosphere of argon gas for a period of 24 h.The black precipitate (3) was subsequently filtered, washed with ethanol, and dried at a temperature of 45 °C for a duration of 6 h.

Plant material and extract preparation of Almond peel
The Almond peel was prepared in April 2022 from the market of Tehran province, Iran and its optimum commercial maturity is available in local market.The voucher specimen has been identified by Sharififar and deposited in the Herbarium Center of Department of Pharmacognosy (KF1234).The collected biomaterial was extensively washed under tap water to remove any particulate sprayed with distilled water and dried.

Synthesis of m-Co 3 O 4 (4)
In order to achieve this objective, a solution of Co(NO 3 ) 2 ⋅6H 2 O (10 g) in distilled water (100 mL) was prepared.Subsequently, Almond peel biotemplate was carefully softened in a mortar and then immersed in the cobalt solution at a 1:1 ratio, followed by stirring for a duration of 12 h.Upon completion, the biotemplate was collected and subjected to calcination at 350 °C for 2 h, resulting in the synthesis of m-Co 3 O 4 (4).

Synthesis of GO-Cu-ASP-m-Co 3 O 4 MOF (5)
GO-Cu-ASP (1 g) was dispersed in distilled water/EtOH (1:1, 50 mL) through the application of ultrasonic irradiation (100 W) for a duration of half the time.Subsequently, m-Co 3 O 4 (1 g) was introduced to the mixture and dispersed for an additional half of the allotted time.The mixture was then transfered to reflux at 75 °C, www.nature.com/scientificreports/while simultaneously undergoing rapid mechanical stirring for a period of 24 h.Following the completion of the reaction, the precipitate (5) collected by using a magnet, and subsequently washed with water and ethanol (1:1) three times and then dried in an oven at a temperature of 70 °C for a duration of 12 h.A stepwise depiction of the synthetic process involved in the formation of the GO-Cu-ASP-m-Co 3 O 4 MOF can be detected in Fig. 6.

Typical procedure for the reduction of nitroarenes
A solution having 0.5 mmol of nitroarene in 3 mL of H 2 O was meticulously prepared and combined with a fresh solution of NaBH 4 (3.75 M in 2 mL H 2 O) and GO-Cu-ASP-m-Co 3 O 4 MOF (30 mg).The mixture was thoroughly stirred, ensuring homogeneity.The progress of the reaction was monitored at two-minute intervals using UV-Vis spectroscopy (200-800 nm).Following the completion of the reaction, the GO-Cu-ASP-m-Co 3 O 4 MOF was magnetically isolated, subjected to a water/ethanol wash, dried, and subsequently employed for another cycle under identical conditions.Conversely, the reaction solution was extracted using ethyl acetate, and a diluted solution (25 mL, 0.2 M) was prepared.The purity of the products was ascertained through GC-MS spectroscopy, while the conversion rates were determined utilizing the data obtained from UV-Vis spectroscopy, employing the subsequent equation:   Continuous stirring was employed until the colored solutions became colorless, and the reaction progress was monitored using UV-Vis spectroscopy (200-800 nm).Upon completion of the reaction, GO-Cu-ASP-m-Co 3 O 4 MOF was magnetically isolated, washed with EtOH/water, dried and subsequently utilized for another cycle under the same conditions.On the other hand, the reaction solution was extracted using ethyl acetate, and a diluted solution (10 mL, 0.1 M) was prepared.The purity of the products was determined using GC-MS spectroscopy, and the conversion rates were calculated based on the data obtained from UV-Vis spectroscopy.

Ethical approval
All applicable international, national, and institutional guidelines for collecting of plant material (Almond peels) were followed.

Conclusion
In conclusion, a magnetic MOF-based catalyst incorporating mesoporous-Co 3 O 4 nanoparticles was successfully synthesized and characterized.The GO-Cu-ASP-m-Co 3 O 4 MOF exhibited exceptional catalytic performance in reduction of nitro compounds, CR and MB under mild conditions.The inclusion of GO-Cu-ASP-m-Co 3 O 4 MOF significantly enhanced catalytic activity and provided stability to copper and m-Co 3 O 4 within the catalyst structure, facilitating better recovery.The reduction progress was monitored using UV-Vis spectroscopy, and the conversion rates were determined.The catalyst displayed remarkable recyclability, maintaining relatively stable catalytic activity over eight runs with only minimal decrease in product conversion.These findings contribute significantly to the advancement of efficient methodologies for decolorizing and eliminating pollutants from wastewater.

1 .
Furthermore, the reduction of CR and MB using GO-Cu-ASP-m-Co 3 O 4 MOF was investigated.The reduction of CR and MB only occurred by NaBH 4 and GO-Cu-ASP-m-Co 3 O 4 MOF under ambient conditions, as monitored by UV-Vis.As depicted in Table 2 and Fig. 5, the reduction of CR and MB resulted in breakdown of Table Reduction reaction of nitroarenes in the present of GO-Cu-ASP-m-Co 3 O 4 MOF a .a Condition: p-nitroarene (0.5 mmol), Catalyst (30 mg), NaBH 4 (7.5 mmol) and H 2 O at r.t b EtOH/H 2 O (1:3).
https://doi.org/10.1038/s41598-024-52708-xwww.nature.com/scientificreports/CR into biphenyl, sodium (4-amino-1-naphthalene)-sulfonate, and nitrogen as well as the formation of LMB (leucomethylene blue).The absorption peaks of CR and MB at 493 and 344 nm and 664 nm, respectively, reduced over time, indicating the progress of the reduction procedure (Fig.5A,B).The reduction of MB was completed within 45 s, with both peaks completely disappearing and the solution changing from dark blue to colorless.Without any catalysts, no change occurred, and the solution remained dark blue.However, the presence of Cu and Co nanoparticles significantly accelerated the reaction, facilitating the rapid absorption of MB from the solution (Fig.5A).Similarly, at the onset of the CR reduction process in the presence of GO-Cu-ASP-m-Co 3 O 4 MOF, two absorption bands were observed at 350 and 498 nm.Gradually, both peaks diminished, and after 8 min, they were completely eliminated, attended by a color change from dark red to colorless.Conversely, this reaction exhibited no changes without catalyst, with the solution remaining dark red.However, with the presence of Cu and Co nanoparticles, significant progress was achieved, leading to the absorption of CR from the reaction solution (Fig.5B).Moving on to compare the performance of GO-Cu-ASP-m-Co 3 O 4 MOF with other catalysts, recent reports on the reduction of 4-NP, MB, and CR were reviewed (TableS2, entries 1-14).As shown in the table, GO-Cu-ASP-m-Co 3 O 4 MOF achieved higher conversions under more favorable reaction conditions and shorter reaction times.Moreover, GO-Cu-ASP-m-Co 3 O 4 MOF catalyst demonstrated easy separation with high stability.

Table 2 .Figure 5 .
Figure 5. Time-dependent UV-Vis spectra for the reduction of (A) MB and (B) CR with NaBH 4 catalyzed by GO-Cu-ASP-m-Co 3 O 4 MOF.